Nucleosides. XX. 1-α-D-Ribofuranosylthymine - ACS Publications

Jack J. Fox. The Divisions of Nucleoprotein Chemistry and Experimental Chemotherapy, Sloan-Kettering Institute for Cancer Research,. Sloan-Kettering D...
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JUXE,1964

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Nucleosides. JIGf

XX. 1-a-D-Ribofuranosylthyminel

FARKAS, LOUISKAPLAN, AND JACK J. Fox

The Divisions of Nucleoprotein Chemistry and Experimental Chemotherapy, Sloan-Kettering Institute for Cancer Research, Sloan-Kettering Division Graduate School of Medical Sciences, Cornell University Medical College, New York d l , New York Received October 22, 1963 “5-Methyluridine” prepared a decade ago by the Hilbert-Johnson procedure is now characterized as l - a - ~ ribofuranosylthymine (11). It is demonstrated that the Hilbert-Johnson reaction yields the known l - p - ~ ribofuranosylthymine (the true 5-methyluridine, I ) as well as its a-anomer, 11. A long-reported “5-methylcytidine” originating from. the same procedure is most probably the a-anomer of true 5-methylcytidine, the latter prepared from I. The failure of these anomeric 1-D-ribofuranosylthymines and 5-methylcytosines to obey Hudson’s Rules of isorotation shows that, optical rotation cannot be used to assign configuration to anomers of pyrimidine nucleosides in general. The glycosyl linkage of the p-anomer ( I ) is cleaved by the pyrimidine phosphorylase of Bacillus subtilis 16; the a-anomer (11)is not cleaved by this enzyme.

their reaction, especially since Naito and Kawakami’o 5-Met hy luridine (I, l-@-D-ribofuranosylt hymine) was recently isolated anomeric 1-D-ribopyranosylthymines synthesized by the Mercuri procedure2 and shown to in a similar Hilbert-Johnson-type condensation. Morepossess the P-configuration by its conversion to spongoover, the “trans rule”*2,13would require that, in the thymidine (1-P-D-arabinofuranosylthymine) via a 2,2’Hilbert-Johnson reaction with poly-0-acylglycosyl anhydronucleoside intermediate.3 Another “&methylhalides, the C-1,C-2 trans anomer should be the preuridine” (11) was reported previously by Roberts and Visser4 by use of the Hilbert-Johnson p r ~ c e d u r e . ~ dominant (if not the sole) product when sugars bearing a 2-acyloxy function are employed. We therefore reStudies on both nucleosides2 showed that I1 differed investigated the Roberts-Visser preparation of “5from I in melting point, mixture melting point, and methyluridine .” optical rotation. Both I and I1 exhibited thymidineTri-0-acetybribofuranosyl bromide was prepared like spectra. Both nucleosides, when treated with from tetra-0-acetyl-@-~-ribofuranose’~ by the method metaperiodate, consumed one mole of oxidant per mole of Zinnerls and was condensed with 2,4-diethoxy-5rapidly without the liberation of formic acid, a behavior methylpyrimidine in anhydrous benzene a t room temconsistent with a furanosyl sugar moiety containing perature for three days. The crude condensate was the a-cis glycol grouping. However, the optical rotasubjected to acid hydrolysis. A mixture of only two tions of the dialdehyde solution obtained from metaperiodate oxidation of I and I1 were different. These nucleosides was obtained in 45% yield from which pure anomers were obtained by fractional crystallization. data suggested2 that the Roberts-Visser “bmethyluri-8’) was identical with 1-@-~One of these ([.ID dine” might be the a-anomer of I ; But, since the ribofuranosylthymine (I) prepared by the Mercuri rotation of I1 was more levorotatory than that for procedure. The other component ( [ a ]-50’) ~ showed authentic 5-methyluridine (I) (Hudson’s Rule of isorotation would require the @-anomer to be more properties similar to “Bmethyluridine” (11) and also gave elemental analyses consistent with a pentosyllevorotatory), the Roberts-Visser nucleoside (11) thymine. remained uncharacterized.2,6 The assignment of the a-configuration to the [ a ] ~ On t,he basis of reporteds optical rotations of several pairs of anomeric 1-(2’-deoxy-~-ribofuranosy~)pyrimi- -50” isomer (11) rests on the following data. I1 exhibits an ultraviolet absorption spectrum similar dines, Fox and co-workers concluded7,sthat assignment of configuration to pyrimidine 2’-deoxynucleosides on to I to show that I1 is an N-1-substituted pyrimidine. the basis of optical rotation alone was certainly unBoth I and I1 consume one mole of metaperiodate per warranted. Recent studies9 with some of these anomole rapidly and do not liberate formic acid in this meric pairs of pyrimidine 2 ’-deoxynucleosides with process. I1 is therefore a furanosyl derivative containn.m.r. spectra and optical rotary dispersion measureing the a-cis glycol grouping. The rotation of the ments supported that conclusion. solution from periodate oxidation of I1 (-25’) differed If this behavior of pyrimidine 2’-deoxynucleosides is These data exclude from that resulting from I (f16’). equally applicable to pyrimidine ribonucleosides, then all 1-P-D-pentofuranosyl- and all I-D-pentopyranosyl“5-methyluridine” (11) might be the a-anomer of I. thymines as possible structures for 11. The rapid If so, it is surprising that only this anomer (obtained (10) (a) T . Naito and T. Kawakami, Chem. Pharm. B d . ( T o k y o ) , 10’ in low yield) was isolated by Roberts and Visser from 627 (1962). (b) These authors observed t h a t the optical rotations of these (1) This investigation was supported in part by funds from the National

Cancer Institute, National Institutes of Health, U.S. Public Health Service ( G r a n t No. CA 03190-07 and CA 03192-07). (2) J. J. Fox, N. Yung, J. Davoll, and G . B. Brown, J. A m . Chem. Sac., 78, 2117 (1956). (3) J . J. Fox, N . Yung, and A. Bendich, ibid.. 19, 2775 (1957). (4) M. Roberts and D. W . Visser, ibid., 74, 668 (1952). (5) See J. J. Fox and I. Wempen, Aduan. Carbohydrate Chem., 14, 283 (1959), for a general review of the Hilbert-Johnson and Mercuri procedures

for pyrimidine nucleoside syntheses. (6) M. Hoffer, R. Duschinsky, J . J. Fox, and N. Yung. J . A m . Chem. Soc., 81,4112 (1959). (7) See ref. 5, P. 340. (8) J . J . Fox. N . c. Yung, I. Wempen, a n d M. Hoffer, J . Am. Chem. Soc.. 83,4066 (1961). (9) R. U. Lemieux and M. Hoffer, Can. J. Chem., 39, 110 (1961).

anomers (as well a s anomeric 1-D-xylopyranosylthymines prepared by a n alternate route) did not obey Hudson’s isorotation rules. However, their configurational assignments t o those glycopyranosyl nucleoside anomers rests, in t h e final analysis, on t h e assignment of the @-configuration t o t h e 1-D-xylopyranosylthymine prepared2,l’ by both the Mercuri and HilbertJohnson procedures. This latter assignment i s derived from the “trans rule.”lz,La Though this assignment is probably correct, i t is not to be considered a s rigorously established. (11) J . J. Fox and I . Goodman, J . A m . Chem. Soc., 73, 3256 (1951). (12) B. R . Baker in Ciba Foundation Symposium, Chemistry and Biology of Purines, 1957, p. 120. (13) For application of the t r a m rule12 t o the Hilbert-Johnson reaction, see ref. 5, p. 336. (14) G. B. Brown, J. A. Davoll. and B. A. Lowy, Biochem. Prep.. 4, 70 (1955). T h e authors are indebted t o Dr. G. B. Brown for a generous supply of tetra-0-acetyl-D-ribofuranose. (15) H . Zinner. Chem. Ber., 83,153 (1950).

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FARKA~, KAPLAN,AND Fox

uptake of metaperiodate excludes the arabino- and xylofuranosylthymines. Thus, we are left with I-cz-Dribofuranosyl- or 1-a-D-lyxofuranosylthymine as possibilities for the structure of 11. The likelihood of I1 being the a-lyxo isomer16is indeed remote. Moreover, the paper electrophoretic behavior (borate buffer, p H 6) of I (+5.6 cm.) and I1 (f5.5 cm.) are almost identical. l-p-~-Lyxofuranosylthymine~~ has a much higher mobility in this system (f7.8 cm.); a similar relationship is obtained when uridine is compared electrophoretically t o its 1-@-D-lyxouracil isomer.’* Finally, both I and I1 and no other nucleosides were found in the same reaction. It is concluded, therefore, that I1 is 1-a-D-ribofuranosylthymine. A purified extract of B. subtilis 16 (a pyrimidinerequiring strain) containing pyrimidine nucleoside phosphorylase was incubated with either pure I1 or pure I. No detectable glycosyl cleavage (formation of thymine) of the a-anomer was observed, whereas the p-anomer under the same conditions underwent -55% cleavage to form thymine. When pure samples of I and I1 were mixed (1: 1) and treated similarly with this enzymatic extract, no inhibition of glycosyl cleavage of the P-nucleoside by the presence of the a-anomer was detected. That the a-anomer is resistant to glycosyl cleavage by nucleoside phosphorylases is expected. Lampen’g demonstrated a decade ago that the Roberts-Visser material (11)was resistant to nucleosidase preparations from E . coli, whereas 1-p-D-ribofuranosylthymine (I) was cleaved by extracts of L. pentosus, as well as E’. coli B.17 General Considerations.-These findings indicate that, as far as the Hilbert-Johnson condensation procedure with ribofuranosyl halide is concerned, the “trans rule” is not wholly operative. The results of Naito and Kawakami with poly-0-acylribo- and -ylopyranosyl halides also show this limitation of the “trans rule” because they also obtained mixtures of anomeric nucleosides by the Hilbert-Johnson method. Roberts and Visser4 also prepared a “5-methylcytidine” by treatment of their condensate obtained from the Hilbert-.Johnson reaction with ammonia. (This condensate was also used by them for the synthesis of 11.) This “.5-methylcytidine” differed in melting point from 5-methylcytidineZ0prepared by the thiation process from 1-p-D-ribofuranosylthymine (I). On the basis of the studies with anomeric 1-D-ribofuranosylthymines reported here, it is more than likely that the Roberts-Visser (‘5-methyl~ytidine”~is 1-a-D-ribofuranosyl-5-methylcytosine. These anomers also fail to obey Hudson’s Rules of isorotation. The a-anomer gives an [ c Y ] * ~ D -78 f. lioJ2’ whereas l-P-D-ribofuranosyl-5-methylcytosine has a specific rotation of +14°.2022 Therefore, on the basis of the rotations of pyrimidine ribonucleosides reported here and previous studies on pyrimidine 2’-deoxyribonucleosides,“-8 it is (16) The synthesis of 1-e-D-lyxofuranosylthymine is underway in our laboratories for use in an enzymatic study. (17) J. J. Fox, J. F. Codington. N. C . Yung. L. Kaplan, and J. 0. Lampen, Jr., J. A m . Chem. Soc.. 8 0 , 5155 (1958). (18) J. F. Codinnton, R . Fecher. and J. J. Fox, ibid., 81, 2794 (1960). (19) J. 0 . Lanipen, “Phosphorus Metabolism,” Vol. 11, W. D. McElroy and B. Glass, Ed., The John Hopkins Press, Baltimore, Md., 1952, p. 368. (20) J. J. Fox, D . Van Praag. I. Wetnpen, I. L. Doerr. L. Cheong, J. E. Knoll, L\I. L. Eidinoff, A . Bendich, and G . B. Brown, J . Am. Chem. Soc., 81, 178 (1959).

VOL.29

obvious that Hudson’s Rules of isorotation cannot be employed to assign anomeric configurations to pyrimidine nucleosides in general.

ExperimentaP Synthesis of I-D-Ribofuranosylthyminehomers.-Tetra-0(15 g., 0.047 mole) was dissolved in acetyl-p-o-ribof~ranose~~ dry ether saturated with hydrogen bromide a t 0’. The flask was tightly stoppered and the solution was allowed to remain for 45 min. a t 0”. The solvent waa removed in vacuo (bath temperature 40’1, the sirupy residue was dissolved in 30 nil. of dry benzene, and the solvent wm again removed in vacuo. This procedure was repeated twice. The sirupy residue was dissolved in 50 ml. of dry benzene and treated with 9.1 g. (0.050 mole) of 2,4-diethoxy-5-methylpyrimidine.The solution was kept in a flask protected from moisture a t room temperature for 3 days, then it was heated a t -60’ for 9 hr. After concentration of the solution to a sirup in vucuo, the residue (23 9.) was dissolved in 150 ml. of dry methanol and treated with 50 ml. of a methanolic solution previously saturated a t 0’ with hydrogen chloride. After 12 hr. a t O o , the methanol wm removed, and the residue was dissolved in 100 ml. of water. The solution was neutralized by portionwise addition with vigorous stirring of silver carbonate. The silver salts were removed by filtration, and the colorless filtrate was concentrated in vacuo (bath temoerature 40”) to a sirup (10 g.). This sirup was dissolved in 30 ml. of methanol and an aliquot was used for further investigation. This solution (5 ml., containing 1.65 g. of crude mtterial) was placed on a cellulose column with n-butyl alcohol-ethanolwater (40: 11: 19).a4 The first eluates contained free pyrimidines (negative periodate test) .Is Later fractions showed ultraviolet absorption a t 266 mu and a positive periodate test. These latter fractions were combined and concentrated to dryness. Upon trituration with a small amount of ethanol, the sirupy residue crystallized (1.02 g.) and the mother liquor was discarded. This crystalline material contained -90% nucleosides by spectrophotometric determination. The total yield of mixed nucleosides was 45y0. The crude crystalline material was dissolved in 5 ml. of hot ethanol and placed in the cold for 2 days. Needles rich in the a-anomer were collected. After three recrystallizations of these needles from ethanol, 180 mg. of 1-a-o-ribofuranosylthymine was obtained, m.p. 175-176”, lit.4 m.p. 175-177”, A,, 268.5mp, [ a ] z 3 ~-50” (c 1.28, water). Anal. Calcd. for CloHlrN2OC: C, 46.50; H , 5.46; N, 10.85. Found: C, 46.51; H, 5.24; N, 10.50. The mother liquors after several days in the cold, deposited tiny spherical-shaped clusters which were almost pure B-ano mer. After two recrystallizations of this material from ethanol, pure 1-p-o-ribofuranosylthymine (169 mg.) waa obtained, m.p. 183184”, lit.2 m.p. 183-185”. A mixture melting point with authentic materiala showed no depression, [ c z ] * ~ D -8” (c 2.3, l ~ water), lit.2 [ ~ r -10”. Metaperiodate Oxidation Studies.-These studies were carried out in a manner similar to those already described.l The consumption of metaperiodate and the rotation of the dialdehyde solutions of these anomers were as follows.

(21) (e 0.05, distilled water) The authors are indebted to Dr. D. W. Visser for a sample of this compound and to Dr. David Fukuahima for the determination of its optical rotation on a 1-mg. sample. Mra. Naishun Miller kindly performed the metaperiodate oxidation of this small sample and found that it consumed one mole of oxidant per mole within three minutes. This consumption of oxidant remained constant over a two-hour period. This data supports a furanosyl structure. A 1-mg. sample of cytidine was used as a control in the metaperiodate study. The ultraviolet absorption spectrum of the Roberts-Visser “5-methylcytidine” at p H values of 1 , 7, and 13 was almost identical with that reported%@ for true 5-methylcytidine, which shows that both nucleosides are 1-substituted 5-methylcytosinee. (22) (e 3.2, distilled water); lit.19 [ o ] D -3’ ( c 2.5, 1.0 N NaOH). (23) All melting points were taken on a Thomas-Hoover capillnry melting point apparatus and are corrected. Microanalyses were performed by Spang Microanalytical Laboratory, Ann Arbor, Mich. (24) L. Hough and J. K. N . Jones. “Methods in Carbohydrate Cheniis-, try.” Vol. I. R . I,. Whistler and M. L. Wolfrom, Ed., Acadetnic Press, Inc., New York, N . Y . , 1962, p. 21. (25) J. A. Cifonelli and F. Smith, Anal. Chem., 46, 1132 (1954).

JUNE, 1964

UNSUBSTITUTED HEPTULOSES Moles of 10,- consumed per mole 2 hr. 12 hr.

@-Anomer( I ) a-Anomer (11)

0.94 0.99

0.97 1.01

[ a ] D of dialdehyde produced

+16' -25"

Chromatographic Studies.-In the ionophoretic system26 requiring borate buffer, pH 6.2, 4 hr., 800 volts, the following migrations were obtained: for the a-anomer, +5.5 cm.; 8anomer, +5.6 cm.; and for 1-/3-D-lyxofuranosylthymine, +7.8 cm. The chromatographic system*' (ethyl acetate-acetic acidwater, 9:2: 1, thin layer chromatography on Merck Silica Gel G.) without benzeneboronic acid present gave, for the a-anomer, Rf 0.60, and, for 5-methyluridine, Rt 0.59. The same system containing 0.5y0 benzeneboronic acid gave these Rf values: for the a-anomer, 0.86, and, for the p-anomer, 0.75. Enzymatic Studies.-Bacillus subtilis 16, a pyrimidine-requiring organism,28was used as a source of pyrimidine nucleoside phosphorylase, since preliminary studies had indicated that extracts of this mutant contained substantial amounts of this enzyme. The organism was grown in the Biogen29 in a chemically defined liquid medium30 supplemented with 0.5 pmole per ml. of uracil. The cells were harvested a t the end of the exponential phase of growth in a Sharples centrifuge and resuspended in 0.05

1471

M phosphate-0.02 M cysteine hydrochloride buffer (pH 7.08); extracts were prepared by their disruption in a 10 KC Raytheon sonic oscillator. Purification of the enzyme was carried out according to the procedure of Tono and Cohen3' to give a preparation puri5ed 14-fold. This preparation was used for the experiments listed in Tables 1-111. A calibration curve relating the amount of thymine formed to the amount of 1-p-n-ribofuranosylthymine initially present in the incubation mixture was obtained. The results are shown in tabular form (Table 11).

TABLE I1 CLEAVAGEOF ~-@-D-RIBOFURANOSYLTHYMINE BY PURIFIED PYRIMIDINE NUCLEOSIDE PHOSPHORYLASE DERIVEDFROM B. subtilis 16a --[.4]--

[Bl-Thymine formed, rrnole/ml.

7--

I-p-D-Ribofuranosylthymine, rmole/ml.

% cleavage. [BI/[AI X 100

1.o 0.42 42 2.0 0.80 40 3.0 1.14 38 4.0 1.47 37 a Each incubation mixture contained 80 pmoles of phosphate buffer, pH 6.95, 12 pmoles of mercaptoethanol, 0.2 ml. of purified TABLE I enzyme preparation, and the amount of ,%anomer as indicated in CLEAVAGEOF ~-D-RIBOFURANOSYLTHYMINES BY PURIFIED a total volume of 2.0 ml. Incubation was carried out a t 36.2'; PYRIMIDINE NUCLEOSIDE PHOSPHORYLASE DERIVEDFROM a t the end of 180 min., the reaction was stopped and the amount B. subtilis 16a of thymine present was determined by the change in optical Time, ---% thymine formed from-density a t 300 mp, pH 13. min.

&Anomer

a-Anomer

30 36 0 60 51 0 90 53 0 180 56 0 a Each incubation mixture contained 80 pmoles of phosphate buffer, pH 6.95, 12 pmoles of mercaptoethanol, 0.2 ml. of purified enzyme preparation, and 6.4 pmoles of the @-anomer or 19.2 pmoles of a-anomer in a total volume of 2.0 ml. Incubation was carried out a t 36.2"; aliquots were removed a t various time intervals and pipetted into 2.8 ml. of 0.1 N NaOH. The thymine present as a result of enzymic action was measured by following the change in optical density a t 300 mp, pH 13. (26) M . P. Gordon, D. M. Intrieri, and G. B. Brown, J. Am. Chem. Soc., 80, 5161 (1958). (27) E. J. Bourne, E. M. Lees, and H. Weigel, J . Chromafog., 11, 253 (1963). (28) Obtained from Dr. R. Guthrie (Children's Hospital, Buffalo, N. Y.) who isolated and characterized this m u t a n t with respect t o its pyrimidine requirements. (29) An instrument for the continuous cultivation of microorganisms (American Sterilizer Co.). (30) R. E. Feeney, J. .4. Garihaldi, and E. M. Humphreys, Arch. Biochem., 17, 435 (1948). (31) H . Tono and S. S. Cohen, J . B i d . Chem., 237, 1271 (1962).

I t is evident that a constant percentage of thymine is formed from the 8-anomer irrespective of its initial concentration. Furthermore, the addition of various levels of the a-anomer to the reaction mixture did not affect the per cent cleavage of the Banomer. These results are shown in Table 111.

TABLE I11

~-~-D-RIBOFURANOSYLTHYMINE UPON CLEAVAGE OF ~-P-D-RIB~FURANOSYLTHYMINE BY PURIFIED PYRIMIDINE

EFFECTOF

NUCLEOSIDE PHOSPHORYLASE^ Y A n o m e r i c mixture[AI IBI &anomer, a-anomer, rmole/ml rmole/rnl.

a

% thymine Thymine formed, rrnole/ml.

formed, [BJ/[.41 X 100

4.0 0 1.43 3.6 0.4 1.34 3.0 1 .o 1.12 Incubation conditions similar to those presented in

36 37 37 Table 11.

Acknowledgment.-The authors express their appreciation to Drs. George B. Brown and C. Chester Stock for their warm and cont'inued interest.

Synthesis of Higher Ketoses by Aldol Reactions.

11. Unsubstituted Heptuloses

ROBERTSCHAFFER Division of PhUsical Chemistry, Aalivnal Bureau of Standards, Washingtvn, D . C. 20234 Received December 10, 1963 Unsubstituted D-erythrose undergoes a mixed aldol reartion with 1,3-dihydroxy-2-propanoneto give D - a l b , ~ a l t i - o -and , ~-gkcco-heptulosesin an over-all yield of 3757,.

Work in this laboratory has shown that substituted higher ketoses' as well as branched-chain higher aldoses2 are obtained by aldol reactions of carbohydrates that (a) are unable to form intramolecular hemiacetal linkages because of blocked y- or &hydroxyl groups, (1) R. Schaffer and H. S. Ishell, J . Org. Chem., 87,3268 (1962). (2) R. Schaffer. J . Am. Chem. Soc.. 81, 542 (1959).

and (b) are precluded from isomerizing to ketoses by substitution of the a-hydroxyl group. Recently, however, the aldol self-addition reaction of an unsubstituted ring-fornaing sugar (D-erythrose to D-gluco-Lglycero-3-octulose) was discovered , and this indicated that a mixed aldol reaction of unsubstituted tetroses (3) R . Schaffer and A. Cohen, J . Org. Chem., 28, 1929 (1963).